Genetically encoded fluorescent sensors of membrane potential

B. J. Baker; H. Mutoh; D. Dimitrov; W. Akemann; A. Perron; Y. Iwamoto; L. Jin; L. B. Cohen; E. Y. Isacoff; V. A. Pieribone; T. Hughes; T. Knöpfel

doi:10.1007/s11068-008-9026-7

Genetically encoded fluorescent sensors of membrane potential

B. J. Baker, H. Mutoh, D. Dimitrov, W. Akemann, A. Perron, Y. Iwamoto, L. Jin, L. B. Cohen, E. Y. Isacoff, V. A. Pieribone, T. Hughes, T. Knöpfel^*

^*Corresponding author for this work

Department of Physics

Research output: Contribution to journal › Journal article › peer-review

84 Citations (Scopus)

Abstract

Imaging activity of neurons in intact brain tissue was conceived several decades ago and, after many years of development, voltage-sensitive dyes now offer the highest spatial and temporal resolution for imaging neuronal functions in the living brain. Further progress in this field is expected from the emergent development of genetically encoded fluorescent sensors of membrane potential. These fluorescent protein (FP) voltage sensors overcome the drawbacks of organic voltage sensitive dyes such as non-specificity of cell staining and the low accessibility of the dye to some cell types. In a transgenic animal, a genetically encoded sensor could in principle be expressed specifically in any cell type and would have the advantage of staining only the cell population determined by the specificity of the promoter used to drive expression. Here we critically review the current status of these developments.

Original language	English
Pages (from-to)	53-67
Number of pages	15
Journal	Brain Cell Biology
Volume	36
Issue number	1-4
DOIs	https://doi.org/10.1007/s11068-008-9026-7
Publication status	Published - Aug 2008

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10.1007/s11068-008-9026-7

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title = "Genetically encoded fluorescent sensors of membrane potential",

abstract = "Imaging activity of neurons in intact brain tissue was conceived several decades ago and, after many years of development, voltage-sensitive dyes now offer the highest spatial and temporal resolution for imaging neuronal functions in the living brain. Further progress in this field is expected from the emergent development of genetically encoded fluorescent sensors of membrane potential. These fluorescent protein (FP) voltage sensors overcome the drawbacks of organic voltage sensitive dyes such as non-specificity of cell staining and the low accessibility of the dye to some cell types. In a transgenic animal, a genetically encoded sensor could in principle be expressed specifically in any cell type and would have the advantage of staining only the cell population determined by the specificity of the promoter used to drive expression. Here we critically review the current status of these developments.",

author = "Baker, {B. J.} and H. Mutoh and D. Dimitrov and W. Akemann and A. Perron and Y. Iwamoto and L. Jin and Cohen, {L. B.} and Isacoff, {E. Y.} and Pieribone, {V. A.} and T. Hughes and T. Kn{\"o}pfel",

note = "The authors thank Dr. Steven Middleton for careful commenting on this article. This article was supported by NIH grant NS057631 (LBC, EYI, VAP, TH, TK) and an intramural grant from RIKEN BSI (TK). Publisher Copyright: {\textcopyright} The Author(s) 2008. ",

year = "2008",

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doi = "10.1007/s11068-008-9026-7",

language = "English",

volume = "36",

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journal = "Brain Cell Biology",

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AU - Baker, B. J.

AU - Mutoh, H.

AU - Dimitrov, D.

AU - Akemann, W.

AU - Perron, A.

AU - Iwamoto, Y.

AU - Jin, L.

AU - Cohen, L. B.

AU - Isacoff, E. Y.

AU - Pieribone, V. A.

AU - Hughes, T.

AU - Knöpfel, T.

N1 - The authors thank Dr. Steven Middleton for careful commenting on this article. This article was supported by NIH grant NS057631 (LBC, EYI, VAP, TH, TK) and an intramural grant from RIKEN BSI (TK). Publisher Copyright: © The Author(s) 2008.

PY - 2008/8

Y1 - 2008/8

N2 - Imaging activity of neurons in intact brain tissue was conceived several decades ago and, after many years of development, voltage-sensitive dyes now offer the highest spatial and temporal resolution for imaging neuronal functions in the living brain. Further progress in this field is expected from the emergent development of genetically encoded fluorescent sensors of membrane potential. These fluorescent protein (FP) voltage sensors overcome the drawbacks of organic voltage sensitive dyes such as non-specificity of cell staining and the low accessibility of the dye to some cell types. In a transgenic animal, a genetically encoded sensor could in principle be expressed specifically in any cell type and would have the advantage of staining only the cell population determined by the specificity of the promoter used to drive expression. Here we critically review the current status of these developments.

AB - Imaging activity of neurons in intact brain tissue was conceived several decades ago and, after many years of development, voltage-sensitive dyes now offer the highest spatial and temporal resolution for imaging neuronal functions in the living brain. Further progress in this field is expected from the emergent development of genetically encoded fluorescent sensors of membrane potential. These fluorescent protein (FP) voltage sensors overcome the drawbacks of organic voltage sensitive dyes such as non-specificity of cell staining and the low accessibility of the dye to some cell types. In a transgenic animal, a genetically encoded sensor could in principle be expressed specifically in any cell type and would have the advantage of staining only the cell population determined by the specificity of the promoter used to drive expression. Here we critically review the current status of these developments.

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SN - 1559-7105

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JO - Brain Cell Biology

JF - Brain Cell Biology

IS - 1-4

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Genetically encoded fluorescent sensors of membrane potential

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